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| United States Patent |
5,539,154
|
|
Nguyen
, et al.
|
July 23, 1996
|
Fluorinated silicon nitride films
Abstract
A plasma enhanced chemical vapor deposition process for producing a
fluorinated silicon nitride film on a substrate is disclosed. The process
utilizes a mixture of silane, perfluorosilane and nitrogen to produce
films of high conformality and stability. The silane and perfluorosilane
in the mixture are in a ratio of 0.05 to 1 on a volume basis. The
preferred silane is SiH.sub.4 and the preferred perfluorosilane is
SiF.sub.4. Films prepared by the process are disclosed and their
properties are described.
| Inventors:
|
Nguyen; Son V. (Hopewell Junction, NY);
Dobuzinsky; David M. (Hopewell Junction, NY);
Dopp; Douglas J. (Wappingers Falls, NY);
Harmon; David L. (Essex Junction, VT)
|
| Assignee:
|
International Business Machines Corporation (Armonk, NY)
|
| Appl. No.:
|
429449 |
| Filed:
|
April 27, 1995 |
| Current U.S. Class: |
174/138C; 174/137R; 174/255; 428/698 |
| Intern'l Class: |
H01C 007/10 |
| Field of Search: |
428/698
174/137 B,256,138 C,255
|
References Cited
U.S. Patent Documents
| 3485666 | Dec., 1969 | Sterling et al. | 427/38.
|
| 4504518 | Mar., 1985 | Ovishinsky et al. | 427/38.
|
| 4668365 | May., 1987 | Foster et al. | 428/698.
|
| 4704300 | Nov., 1987 | Yamazaki | 427/38.
|
| 4720395 | Jan., 1988 | Foster | 427/255.
|
| 4759947 | Jul., 1988 | Ishihara et al. | 427/38.
|
| 4786612 | Nov., 1988 | Yau et al. | 437/47.
|
| 4877641 | Oct., 1989 | Dory | 427/38.
|
| 5045346 | Sep., 1991 | Tabasky et al. | 427/39.
|
| Foreign Patent Documents |
| 277766 | Aug., 1988 | EP | .
|
Other References
"Low Temperature Silicon Nitride Deposition Using Microwave-Excited Active
Nitrogen," by Shibagaki et al.; Japanese Journal of Applied Physics, vol.
17, Supplement 17-1, (1978), pp. 215-221.
|
Primary Examiner: Turner; A. A.
Attorney, Agent or Firm: Heslin & Rothenberg
Parent Case Text
CROSS-REFERENCE TO RELATED APPLICATION
This application is a division of application Ser. No. 07/998,194, filed
Dec. 29, 1992 now U.S. Pat. No. 5,462,812, which is a divisional of our
prior U.S. application Ser. No. 07/814,973, filed Dec. 24, 1991 now U.S.
Pat. No. 5,204,138.
Claims
We claim:
1. A semiconductor device comprising a substrate and a highly conformal
fluorinated silicon nitride film, wherein the film contains from about 15
to about 20 atom % fluorine, and has a dielectric constant between 6.0 and
6.7; a refractive index from 1.64 to 1.80; and a surface state density of
from about 6.times.10.sup.11 to about 8.times.10.sup.11 charges/cm.sup.2.
2. A semiconductor device according to claim 1 wherein said silicon nitride
film is from 5 to 50 nm in thickness.
3. A semiconductor device comprising a substrate and a highly conformal
fluorinated silicon nitride film deposited thereon, wherein the film is
produced by the process of introducing into a film-forming chamber at 4 to
6 torr and 400.degree. to 450.degree. C. a flow of silane,
tetrafluorosilane and nitrogen at a rate of 4 to 10 sccm silane, 20 sccm
tetrafluorosilane, 5000 sccm nitrogen; and applying electromagnetic
radiation in the range from 400 Khz to 100 Mhz, and a power density of 0.6
to 5.5 watt/cm.sup.2.
4. The semiconductor device of claim 1, characterized in that the silicon
nitride film does not exhibit breakdown below 7 MV/cm.
5. The semiconductor device of claim 1, characterized in that the silicon
nitride film absorbs less than 2% by weight of water after immersion for
20 minutes in water at 100 degrees Centigrade.
6. The semiconductor device of claim 1, characterized in that the silicon
nitride film exhibits less than 1% change in thickness after annealing at
850 degrees Centigrade for 30 minutes.
7. The semiconductor device of claim 1, wherein the silicon nitride film
contains less than 1 atom % of oxygen.
Description
TECHNICAL FIELD
This invention relates to a plasma enhanced chemical vapor deposition
(PECVD) process for producing a fluorinated silicon nitride film on a
substrate and to a film so produced. The process utilizes a mixture of
silane, perfluorosilane, and nitrogen to produce films of high
conformality and stability.
BACKGROUND ART
The trend toward ever greater device densities, smaller minimum feature
sizes, and smaller separations in integrated circuits imposes increasingly
stringent requirements on the basic fabrication steps of masking, film
formation (by deposition or growth), doping and etching. Ultra large scale
integrating (ULSI) devices require the fabrication of circuits on the
nanometer (nm) scale. For certain applications in such circuits, silicon
nitride films offer advantages over silicon oxide films. For example, as a
collar material for storage trenches, a film of silicon nitride 30 nm
thick can provide comparable dielectric properties to a 100 nm silicon
dioxide film. In addition, because stable fluorinated silicon nitride is
not permeable to oxygen, the surface of the substrate (usually silicon) is
protected from oxidation. Silicon nitride films that are stable and
conformal would be particularly useful for low temperature side wall
spacers for sub-micron gates, for high temperature annealing caps for GaAs
dopant activation and for interlevel dielectric materials.
However, the advantages of a silicon nitride film can only be realized if a
thin film can be made by a process that is compatible with the technology
for manufacturing ULSI devices. The process must avoid high temperatures
and incompatible chemistry. Chemical vapor deposition processes for
producing silicon nitride films are known.
U.S. Pat. No. 4,668,365 (Foster et al.) discloses a plasma CVD reactor and
an associated process using a magnetic field to provide silicon nitride
films. This process uses silane as a source of silicon and molecular
nitrogen as the source of nitrogen.
U.S. Pat. No. 3,485,666 (Sterling et al.) discloses a method of directly
depositing an electrically insulating, amorphous, coherent, solid layer of
silicon nitride produced from silane and ammonia.
U.S. Pat. No. 4,786,612 (Yau et al.) discloses a plasma enhanced CVD
process for fabricating a silicon nitride resistor in a semiconductor
device. The process uses a mixture of silane, nitrogen and ammonia.
U.S. Pat. No. 4,504,518 (Ovshinsky et al.) discloses a plasma enhanced CVD
process for producing a silicon nitride film which uses microwave
radiation to generate the plasma. Mixtures of silane and nitrogen or
ammonia are disclosed as reaction gases and mixtures of silicon
tetrafluoride and nitrogen or ammonia are also disclosed.
Shibagaki et al. [Japanese Journal of Applied Physics, 17, suppl 17,
215-221 (1978)] discloses the deposition of the silicon nitride film by
the reaction of silane with molecular nitrogen using microwave energy to
generate the plasma.
Silicon nitride films of the foregoing art have been limited in their
utility by the presence of silicon hydrogen bonds in the silicon nitride
film. Some of the silicon hydrogen bonds are relatively weak and tend to
dissociate with subsequent migration of hydrogen through the silicon
nitride material. In many of the films of the art the concentration of
hydrogen in the deposited silicon nitride can be as high as 25-35 atom
percent. The presence of hydrogen in films that are deposited relatively
early in the integrated circuit fabrication process, and the hydrogen
diffusion which results during subsequent fabrication, can cause
non-uniform electrical characteristics and adhesion problems at interfaces
of the film.
There has thus been a strong incentive to produce silicon nitride having a
low hydrogen content or having strongly bonded hydrogen that is not
mobile. However, the removal of hydrogen by annealing appears to have led
to chemical instability such that the film exhibits film stress and poor
adhesion. The drawback of this approach to lowered hydrogen has led to a
search for plasma processes which employ gases that reduce or stabilize
hydrogen in the silicon nitride. The incorporation of fluorine into the
silicon nitride film obviates a number of these problems. Although a
precise explanation for the combination of fluorine, hydrogen, nitrogen
and silicon into silicon nitride layers is not available, it is believed
that fluorine present in the plasma preferentially bonds with silicon in
the silicon nitride material either preventing formation of
silicon-hydrogen bonds or replacing such bonds with silicon-fluorine
bonds. It would seem that providing an abundance of fluorine atoms would
solve the problem. However the presence of excess fluorine in the plasma
results in the creation of nitrogen-fluorine bonds and SiF.sub.2 linkages.
The presence of nitrogen-fluorine bonds is not desirable because they lead
to a substantial chemical degradation in the resulting silicon nitride
film. Similarly SiF.sub.2 linkages are extremely sensitive to degradation
by moisture. Clearly an appropriate ratio of silicon and nitrogen to
fluorine is required to produce the desired stoichiometry.
U.S. Pat. No. 4,720,395 (Foster) discloses a thermal CVD process for
forming a silicon nitride film. Disilane and NF.sub.3 in a mole ratio of
0.5-3.0 are employed as the sources of silicon, nitrogen, and fluorine.
The films are characterized only by their refractive indices.
U.S. Pat. No. 4,704,300 (Yamazaki) discloses a plasma CVD process for
forming a fluorinated silicon nitride film. Silicon fluoride is fed into
the reactor in the form of SiF.sub.4 and converted in situ to a mixture of
SiF.sub.4 and SiF.sub.2 which then reacts with nitrogen, ammonia or
nitrogen fluoride to provide the silicon nitride film. The process does
not employ silane as a reactant. The films are stated to have a surface
density of 3.times.10.sup.11 charges/cm.sup.2 or less.
European Application 277,766 (Chang et al.) discloses a plasma CVD process
for forming a silicon nitride film. The examples employ mixtures of
silane, NF.sub.3, and nitrogen. The generic description indicates that
hydrazine or ammonia may be used in place of NF.sub.3 and SiH.sub.4 may be
replaced by Si.sub.2 H.sub.4 or chlorinated or partially fluorinated
silanes. The films are stated to have breakdown voltages of 4 MV/cm and
dielectric constants of 4 to 5.
The foregoing references disclose methods for producing fluorinated silicon
nitride films, but all have drawbacks. The use of NH.sub.3, as suggested
by Chang and by Yamazaki, leads to films having lower long-term chemical
stability than films made from N.sub.2. The use of NF.sub.3, as suggested
by Chang and by Foster, leads to etching of the substrate during the
initial deposition step, which is usually undesirable. Moreover, the
production of silicon-fluorine bonds using NF.sub.3 as the source of
fluorine requires a multi-step dissociation and recombination reaction
which is inherently less attractive than starting with silicon-fluorine
bonds. The use of hydrogen fluoride as suggested by Chang is difficult to
control; both NF.sub.3 and HF are highly corrosive materials.
There thus exists a need for an easily controlled, predictable CVD process
for producing fluorinated silicon nitride films that are stable, conformal
and compatible with other steps in the fabrication of integrated circuits.
The term silicon nitride as used herein means a composition of approximate
stoichiometry Si.sub.3 N.sub.4 and fluorinated silicon nitride describes
compositions of empirical formulae Si.sub.3 N.sub.x F.sub.y H.sub.z where
x is from 3 to 4, y is from 0.01 to 1.15 and z is from 0.7 to 5. The
generic term silane includes SiH.sub.4, Si.sub.2 H.sub.6, Si.sub.3 H.sub.8
and other silanes of empirical formula Si.sub.n H.sub.(2n+2). The generic
term perfluorosilane includes SiF.sub.4, Si.sub.2 F.sub.6, Si.sub.3
F.sub.8 and other perfluorosilanes of empirical formula Si.sub.n
F.sub.(2n+2).
DISCLOSURE OF INVENTION
It is an object of the invention to provide a silicon nitride film for ULSI
circuit fabrication that is stable on long term air exposure, that is
stable to high temperature annealing and that has very good conformality.
It is a further object to provide a silicon nitride deposition process that
can be easily and reproducibly modulated to incorporate variable ratios of
fluorine and hydrogen in a predictable fashion.
It is a further object to provide a process that is compatible with
structures and compositions that are commonly part of ULSI devices.
It is a further object to provide semiconductor devices that utilize a
fluorinated nitride dielectric film of 5 to 50 nm thickness.
The invention relates to a process for producing a fluorinated silicon
nitride film on a substrate comprising introducing into a film forming
chamber a mixture of a silane, a perfluorosilane and nitrogen and applying
electromagnetic radiation to the mixture to produce a plasma whereby a
deposition film is formed on a substrate. The silane and perfluorosilane
in the mixture are in a ratio of about 0.05 to about 3 on a volume basis,
preferably 0.05 to 1, more preferably about 0.2 to about 0.6, most
preferably about 0.5. The preferred silanes are SiH.sub.4, Si.sub.2
H.sub.6 and Si.sub.3 H.sub.8 ; the preferred perfluorosilanes are
SiF.sub.4, Si.sub.2 F.sub.6 and Si.sub.3 F.sub.8. The most preferred
silane is SiH.sub.4 and the most preferred perfluorosilane is SiF.sub.4.
Considerable variation is allowed in other conventional CVD process
variables. The electromagnetic radiation can be of any frequency from low
radio frequencies to microwaves; radio frequencies are preferred, in
particular frequencies of 400 Khz to 100 Mkhz, more preferably 10 to 50
Mhz, most preferably about 13-14 Mhz. The power density of the radiation
source is preferably from about 0.6 to about 5.5 watt/cm.sup.2, more
preferably about 1-2 watt/cm.sup.2. It is preferred that the film forming
chamber be maintained at about 2 to about 10 torr and about 300.degree. to
about 600.degree. C., more preferably about 4 to about 6 torr and about
400.degree. to about 450.degree. C. The preferred embodiment comprises a
mixture of 20 parts of silicon tetrafluoride, from 1 to 20 parts silane,
and from 100 to 10,000 parts nitrogen. In a preferred process the silicon
tetrafluoride is introduced into the chamber at a rate of about 10 to
about 70 standard cubic centimeters per minute (sccm). In a more preferred
embodiment the silicon tetrafluoride is introduced into the chamber at a
rate of about 20 sccm, nitrogen at a rate of about 5,000 sccm and silane
at a rate of about 4-10 sccm. A preferred ratio of the combination of
silane and perfluorosilane to nitrogen is about 0.005 to about 0.025 by
volume.
In another aspect, the invention relates to films produced by the inventive
process, and, in particular, to a highly conformal fluorinated silicon
nitride film containing from about 15 to about 20 atom % fluorine, and
having a dielectric constant between 6.0 and 6.7, a refractive index from
1.64 to 1.80, and a surface state density of from 6.times.10.sup.11 to
8.times.10.sup.11 charges/cm.sup.2. The film may be further characterized
in that it contains less than 1 atom % of oxygen. The film does not
exhibit breakdown below 7 MV/cm; it absorbs less than 2% by weight of
water after immersion for 20 minutes in water at 100.degree. C.; and it
exhibits less than 1% change in thickness after annealing at 850.degree.
C. for 30 minutes.
In another aspect the invention relates to a semiconductor device
comprising a substrate and a fluorinated silicon nitride film as described
above. In a preferred embodiment the silicon nitride film is from 5 to 50
nm in thickness.
Because the structure of the film is difficult to specify with precision,
the invention may also be described as a product described as a
product-by-process. In this aspect the invention relates to a fluorinated
silicon nitride film produced by the process of introducing into a
film-forming chamber at 4 to 6 torr and 400.degree. to 450.degree. C. a
flow of silane, tetrafluorosilane and nitrogen at a rate of 4 to 10 sccm
silane: 20 sccm tetrafluorosilane: 5000 sccm nitrogen, and applying
electromagnetic radiation in the range from 400 Khz to 100 Mhz and a power
density of 0.6 to 5.5 watt/cm.sup.2 whereby a highly conformal fluorinated
silicon nitride film is formed. This film may be further characterized in
that it contains from about 15 to about 20 atom % of fluorine and has a
dielectric constant between 6.0 and 6.7 and a refractive index from 1.64
to 1.80.
Semiconductor devices may be fabricated incorporating fluorinated silicon
nitride films as described above by technology well known in the art.
BRIEF DESCRIPTION OF THE DRAWINGS
The foregoing and other objects, features and advantages of the invention
will be apparent from the following more particular description of
preferred embodiments of the invention, as illustrated in the accompanying
drawings.
FIG. 1 is a plot of deposition rate and refractive index as a function of
silane flow at 20 sccm of SiF.sub.4 ;
FIGS. 2, 3, and 4 are X-ray photoelectron spectroscopic depth profiles of
films of the invention. FIG. 2 is of a silicon nitride layer deposited
from a reaction gas mixture of silane and silicon tetrafluoride having a
ratio of 0.25, FIG. 3 is of a silicon nitride film deposited from a
reaction gas mixture having a ratio of 0.5, and FIG. 4 is from a ratio of
1; and
FIG. 5 is a plot of percent thickness loss in annealing versus silane flow
rate at 20 sccm of SiF.sub.4.
BEST MODE FOR CARRYING OUT THE INVENTION
The improved low temperature silicon nitride film PECVD process of this
invention comprises introducing a mixture of a silane, a perfluorosilane,
and nitrogen into a film forming chamber and applying electromagnetic
radiation to the mixture of gases to produce a plasma, as a result of
which a fluorinated silicon nitride layer is deposited on the substrate. A
critical feature of the inventive process is the particular mixture of
source gases for the fluorinated silicon nitride and their
volume-to-volume (v/v) ratio.
One source of the silicon is a silane, which may preferably be SiH.sub.4,
Si.sub.2 H.sub.6 or Si.sub.3 H.sub.8, most preferably SiH.sub.4. A second
source of silicon and a source of fluorine is a perfluorosilane, which may
preferably be SiF.sub.4, Si.sub.2 F.sub.6, or Si.sub.3 F.sub.8, most
preferably SiF.sub.4. Si.sub.3 H.sub.8, Si.sub.3 F.sub.8 and higher
molecular weight silicon compounds are liquids at STP. They are, however,
gases at the 300.degree.-600.degree. C. operating temperature of the
process, and the term gas in this context thus includes aerosols and
vapors produced from the interaction of the discharge with the liquids.
The ratio of silane to perfluorosilane determines the characteristics of
the film that is deposited. In the text that follows ratios are on a v/v
basis unless otherwise indicated. When the ratio of silane to
perfluorosilane is about 0.05 to about 1, stable and uniform silicon
nitride films are deposited. Films deposited when the ratio is greater
than 1 and up to about 3 can be made and may be suitable for some
applications, however when the ratio is above 3 they are generally
unstable and react easily with water vapor upon exposure to air to form
ammonium silicon hexafluoride. Mixtures having a ratio from about 0.2 to
about 0.6 are particularly well suited for fabricating fluorinated silicon
nitride films for ULSI devices because these films show less than 2%
thickness reduction after annealing in nitrogen for 30 minutes at
900.degree. C., they are very stable in air, and they have very high
conformality as discussed below.
The source of nitrogen for the silicon nitride is molecular nitrogen, which
functions both as a reactant and as a carrier gas in the process of the
invention. Because it is acting as a carrier gas, nitrogen is always
present in great excess and commonly will represent from 100 to 10,000
parts per 20 parts of silicon tetrafluoride.
The film forming chamber used in the present experiments was an AME 5000
(available from Applied Materials, Inc., Santa Clara, Calif.) but the
chamber is not critical, and other suitable chambers are commercially
available and their operation is well known in the art. In the operation
of a film forming chamber, the applied voltage, frequency, system
pressure, and gas flow rates are all interdependent, but may be varied
over a wide range consistent with the basic requirement of establishing
the plasma. Thus, for a higher pressure the voltage and/or frequency will
have to be raised. Conversely, for lower pressures the voltage and
frequency may be reduced. For the purpose of depositing 30 to 100 nm films
of fluorinated silicon nitride with high precision and uniformity, the
optimal radio frequency is from 10 to 50 Mhz. However, any electromagnetic
radiation that is capable of producing a plasma will function in the
inventive process, and radio frequencies from 400 Khz to 100 Mhz are
particularly suitable. A 13 to 14 Mhz frequency was used for convenience.
The power density can be from about 0.6 to 5.5 watts/cm.sup.2 ; 1 to 2 is
optimal. The temperature of the chamber is maintained at 300.degree. to
600.degree. C., preferably about 400.degree. to 450.degree. C., and the
pressure is maintained at 2 to 10 torr preferably 4 to 6 torr.
In the case where 30 to 100 nm films of fluorinated silicon nitride are
being deposited for ULSI circuits it is desirable to keep the rate of
deposition at 30 to 150 nm per minute. However, for other applications it
may be desirable to increase the flow rate of the silane and
perfluorosilane gases so that a deposition rate of up to 300 nm per minute
can be obtained. The nature of the film is determined by the ratio of the
silane to perfluorosilane; modifying the flow rate of the mixture of gases
will primarily modulate the rate of deposition and not the nature of the
film. For 30 to 100 nm films, a flow rate of from 10 to 70 standard cubic
centimeters per minute (sccm) for the silicon tetrafluoride has been found
particularly suitable. The rate of introduction of silane is then adjusted
to provide the proper proportion in relation to the flow rate of the
silicon tetrafluoride. A flow rate of 5000 sccm of nitrogen has been found
to give good uniformity film deposition at 5 to 40 sccm of silane and
silicon tetrafluoride.
The substrate may be any material on which a silicon nitride film is
desired; for example, silicon wafers, plastic resin, glass or metal
objects or films, gallium arsenide layers or any semi-conductor layer or
device.
In a representative example of the process of the invention, stable
fluorinated silicon nitride films were deposited on a p-type silicon
substrate using a chemical vapor deposition process on a single wafer
system in an AME 5000 chamber. Ultra high purity silicon tetrafluoride,
silane, and nitrogen were used as reactant gases. The silicon
tetrafluoride was provided at 20 sccm, the silane at 10 sccm, and the
nitrogen at 5000 sccm. The power density was 1.45 watts per square
centimeter, the temperature was 400.degree. C., the pressure was 5 torr
and the electrode spacing was 0.8 to 1.2 centimeters. Under these
conditions the film deposition rate was 48 to 60 nm per minute.
The bonding and composition of fluorinated silicon nitride films were
analyzed by Fourier transform infrared (FTIR), X-ray photoelectron
spectroscopy (XPS) and, for hydrogen, nuclear reaction analysis. MOS
(Al/nitride/p-Si substrate) electrical measurements were used to study the
electrical characteristics of 40 nm fluorinated nitride films. The
stability of fluorinated silicon nitride as deposited and after annealing
at 700.degree. to 900.degree. C. in nitrogen for 30 minutes was examined.
The step coverage conformality of the films was examined over a silicon
trench structure and over 500 nm aluminum metal lines. Ellipsometic
measurements of refractive index were also obtained. In general, an
increase in refractive index reflects an increase in silicon content and
conversely a decrease in refractive index indicates an increase in
nitrogen content.
FIG. 1 shows a typical variation of fluorinated silicon nitride deposition
rate and refractive index as a function of silane flow when silicon
tetrafluoride is held constant at 20 sccm under center line deposition
conditions (5000 sccm N.sub.2, 5 torr, 440.degree. C., 1.4
watts/cm.sup.2). The refractive index, i.e. the composition of the
fluorinated silicon nitride film, remains relatively constant as the ratio
is increased from 0.05 to 1; above the ratio of 1, the refractive index
begins to increase. The refractive index, as well as the film uniformity
and the deposition rates were studied as a function of pressure, power of
the electromagnetic radiation and the silane to silicon tetrafluoride flow
ratio. Deposition rate and uniformity generally increase with increasing
RF power and with decreasing silane to silicon tetrafluoride flow ratio.
Increased pressure tends to reduce the deposition rate and the uniformity.
Film uniformity of fluorinated silicon nitride deposited as described in
the example above is excellent; there is less than 3.5% variation in film
thickness within a range of three standard deviations.
FTIR spectra of stable fluorinated silicon nitride films show the presence
of silicon-nitrogen and silicon-fluorine bonds at 920 to 960 cm.sup.-1 ;
nitrogen-hydrogen bonds are also evident at 1180 and 3350 cm.sup.-1 ;
there is no detectable silicon-hydrogen bond stretching in the region
around 2200 cm.sup.-1.
FIGS. 2, 3, and 4 are graphs derived from XPS showing atom percent of each
element in the film as a function of depth into the film. The y-axis
represents from 0 to 100 atom percent of the element in question; the
x-axis represents sputtering time from 0 to 540 seconds. Thus, the left
edge of the graph may be considered the surface of the silicon nitride
layer and the region in which the silicon curve begins to climb toward 100
atom percent from about 60 atom percent may be thought of as the interface
between the silicon nitride layer and the silicon substrate. FIG. 2 is the
film deposited at a SiH.sub.4 /SiF.sub.4 ratio of 0.25; FIG. 3 is at a
ratio of 0.5 and FIG. 4 is at a ratio of 1.0. It will be noted that oxygen
has intruded only marginally into the surface when the ratio is below 0.5.
These curves are substantially unchanged after six to twelve months'
exposure to ambient air, indicating the remarkable chemical stability of
the films in which the ratio is below 0.5. The XPS depth profiles shown in
FIGS. 2 and 3 indicate that these films are silicon rich, contain up to
17% fluorine, and are oxidized only shallowly by post-deposition surface
oxidation. The hydrogen content of the films, which is obtained from
nuclear reaction analysis, is 5 to 6 atom percent in films generated from
mixtures where the ratio of silane to silicon tetrafluoride is below 0.5.
The hydrogen content increases to 14 atom percent and the fluorine
concentration decreases correspondingly as the ratio increases above 0.5.
Preferred films contain from 15 to 20 atom percent of fluorine and less
than 1 atom percent oxygen.
The stable fluorinated silicon nitride films show less than 2% thickness
reduction after annealing in nitrogen at 900.degree. for 30 minutes. This
compares to a typical thickness reduction of 12% to 15% for conventional
plasma silicon nitride films after the same annealing. FIG. 5 shows the
percent of film thickness that is lost upon annealing as a function of
silane flow (i.e. SiH.sub.4 /SiF.sub.4 ratio) in a deposition process
carried out at 20 sccm SiF.sub.4, 5000 sccm N.sub.2 and other parameters
as before. The stability of films with ratio below 3 is quite good and
below 0.5 is outstanding. Preferred films show less than 1% thickness
change after annealing at 850.degree. C. for 30 minutes in hydrogen,
nitrogen, or nitrogen-oxygen mixtures.
MOS electrical measurements of 36 to 40 nm films show good breakdown
characteristics (7 to 8 MV/cm), stable flat band voltage shifts with good
distribution (-1.98 to -2.07 V) and significant surface interface trap
charge (Qss=6-8.times.10.sup.11 charge/cm.sup.2). Stable fluorinated
nitride films have dielectric constants between 6 and 6.7 and breakdown
voltages of 7 to 8 MV/cm. The films of the invention also show very high
conformality--greater than 80%--over silicon trench structures having a 3
to 1 aspect ratio. Although the fluorinated silicon nitride films show
excellent conformality on silicon trenches, the conformality on 500 nm
aluminum line structures is less than 50%. This may be due to the initial
formation of aluminum fluoride on the aluminum surface.
The films prepared within the preferred parameters described above and with
silane flow of 4 to 10 sccm are extremely stable, showing no measurable
(i.e. less than 2%) water absorption after immersing in boiling water for
20 minutes.
Stress measurements of 1 .mu.m films show that all fluorinated nitride
films have tensile stress in the range of 1.5-2.0.times.10.sup.9
dyne/cm.sup.2.
While the invention has been particularly shown and described with
reference to preferred embodiments thereof, it will be understood by those
skilled in the art that other changes in form and details may be made
therein without departing from the spirit and scope of the invention.
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